V. Manoj Siva

TL;DR: In this article, a mechanism of heat conduction behind the thermal conductivity enhancement observed in graphene nanofluids has been proposed based on the transient hot wire (TWHW) method.

TL;DR: In this paper, the influence of flow maldistribution on temperature distribution in parallel microchannel system was investigated and it was observed that the flow distribution among the channels improves significantly with a decrease in the channel hydraulic diameter due to higher pressure drop offered by each individual channels simultaneously.

TL;DR: In this article, a dimensionally consistent analytic model was proposed to determine and explain the viscosity of polydispersed GNSs, which was found to be in agreement with the GNS experimental data, and even for CNT (diameter 20nm, length 10μm) and nano-alumina (45nm) suspensions.

TL;DR: In this article, a physical mechanism for the enhanced viscosity over the base fluids has been proposed for the poly-dispersed GNSs and its behavior with temperature and concentration have been experimentally determined.

TL;DR: In this paper, an extensive experimental study is carried out where in the parameters affecting the flow maldistribution such as number of channels, area of cross section of the manifold, channel hydraulic diameter, and Reynolds number are varied to study their effect on the pressure drop across the parallel channels designed for liquid cooling of a CPU.